CN104080627A

CN104080627A - Vehicle control system

Info

Publication number: CN104080627A
Application number: CN201280068175.5A
Authority: CN
Inventors: 菊池宏信; 平山胜彦
Original assignee: Nissan Motor Co Ltd
Current assignee: Nissan Motor Co Ltd
Priority date: 2012-01-26
Filing date: 2012-12-27
Publication date: 2014-10-01
Anticipated expiration: 2032-12-27
Also published as: US20140358371A1; EP2808189B1; WO2013111504A1; EP2808189A1; EP2808189A4; JPWO2013111504A1; CN104080627B; JP5713121B2; US9073398B2

Abstract

The wheel speed of front wheels detected by front wheel speed sensors (5FL, 5FR) is held back and the wheel speed of rear wheels is estimated, and when the magnitudes of the amplitudes of the frequencies of the estimated rear wheel speed and the detected front wheel speed are treated as frequency scalar quantities, a damping force control amount for S/A(3) is calculated on the basis of the frequency scalar quantities.

Description

Vehicle control device

Technical Field

The present invention relates to a control device for controlling a state of a vehicle.

Background

Patent document 1 discloses one of the following techniques: the vibration state of the vehicle caused by the disturbance is estimated from the wheel speed variation of each wheel, and the damping force of the damping force variable absorber is changed.

Patent document 1: japanese laid-open patent publication No. 2009-

Disclosure of Invention

Problems to be solved by the invention

Since the change in the value of the wheel speed sensor attached to the rear wheel of the differential gear (differential gear) with respect to the inclination of the axle caused by the stroke of the suspension is small, the estimation accuracy of the vibration state of the vehicle is low, and the vibration damping performance is deteriorated.

The present invention has been made in view of the above problems, and an object thereof is to provide a vehicle control device capable of estimating a vibration state of a vehicle with high accuracy and improving vibration damping performance.

Means for solving the problems

In order to achieve the above object, a vehicle control device according to the present invention estimates a wheel speed of a rear wheel by delaying a wheel speed of a front wheel detected by a front wheel speed detecting means, and calculates a damping force control amount of a damping force variable absorber based on a frequency scalar when a magnitude of an amplitude of a frequency of the detected front wheel speed and the estimated rear wheel speed is set to the frequency scalar.

ADVANTAGEOUS EFFECTS OF INVENTION

Since the change in the value of the wheel speed sensor of the front wheel attached to the axle with respect to the inclination of the axle associated with the stroke is large, the vibration state of the vehicle can be estimated with high accuracy. Further, since the damping force control amount of the damping force variable damper is calculated based on the frequency scalar quantity, even when the estimated wheel speed of the rear wheel and the actual wheel speed of the rear wheel are out of phase, the vibration damping performance can be improved based on the vibration state of the vehicle estimated with high accuracy without causing deterioration of the vibration damping performance.

Drawings

Fig. 1 is a system schematic diagram showing a vehicle control device according to embodiment 1.

Fig. 2 is a control block diagram showing a control structure of a vehicle control device according to embodiment 1.

Fig. 3 is a control block diagram showing the configuration of the roll-rate restraining control of embodiment 1.

Fig. 4 is a timing chart showing the envelope waveform forming process of the roll rate suppression control of embodiment 1.

Fig. 5 is a control block diagram showing the configuration of the running state estimating unit according to embodiment 1.

Fig. 6 is a control block diagram showing the control contents of the stroke speed calculation unit in embodiment 1.

Fig. 7 is a block diagram showing the configuration of the reference wheel speed calculation unit in embodiment 1.

Fig. 8 is a flowchart showing a rear wheel speed estimation process of embodiment 1.

Fig. 9 is a schematic diagram showing a vehicle body vibration model.

Fig. 10 is a control block diagram showing the process of calculating the control amount of each actuator when pitch control is performed according to embodiment 1.

Fig. 11 is a control block diagram showing the brake-pitch control according to embodiment 1.

Fig. 12 is a graph in which the wheel speed frequency characteristic detected by the wheel speed sensor and the stroke frequency characteristic of the stroke sensor not mounted in the embodiment are plotted at the same time.

Fig. 13 is a control block diagram showing frequency-dependent control in sprung vibration damping control according to embodiment 1.

Fig. 14 is a correlation diagram showing human sensory characteristics in each frequency region.

Fig. 15 is a characteristic diagram showing the relationship between the vibration mixing ratio in the empty space region and the damping force in the frequency-sensitive control of example 1.

Fig. 16 is a diagram showing a wheel speed frequency characteristic detected by the wheel speed sensor under a certain running condition.

Fig. 17 is a block diagram showing a control structure of the unsprung vibration damping control in embodiment 1.

Fig. 18 is a control block diagram showing a control structure of the damping force control unit of embodiment 1.

Fig. 19 is a flowchart showing the damping coefficient arbitration process in the standard mode of embodiment 1.

Fig. 20 is a flowchart showing the damping coefficient arbitration process in the sport mode of embodiment 1.

Fig. 21 is a flowchart showing the damping coefficient arbitration process in the comfort mode of embodiment 1.

Fig. 22 is a flowchart showing the damping coefficient arbitration process in the high-speed mode of embodiment 1.

Fig. 23 is a time chart showing changes in damping coefficient when the vehicle travels on a rough road surface or a rough road surface.

Fig. 24 is a flowchart showing a mode selection process based on the running state in the damping coefficient arbitration unit in embodiment 1.

Description of the reference numerals

1: an engine; 1 a: an engine controller; 2: a brake control component; 2 a: a brake controller; 3: S/A (damping force variable shock absorber); 3 a: an S/A controller; 5: a wheel speed sensor; 6: an integral sensor; 7: a rotation angle sensor; 8: a vehicle speed sensor; 20: a brake; 31: a driver input control unit; 32: a driving state estimation unit; 33: a sprung vibration damping control unit; 33 a: a ceiling control section; 33 b: a frequency induction control unit; 34: an unsprung vibration damping control unit; 35: a damping force control unit; 305 a: a wheel speed estimating section for a sprung rear wheel; 305 b: a wheel speed estimating section for the unsprung rear wheel vehicle; 331: a first target attitude control amount calculation unit; 332: an engine attitude control amount calculation unit; 333: a second target attitude control amount calculation unit; 334: a brake attitude control amount calculation unit; 335: a third target attitude control amount calculation unit; 336: and a damper attitude control amount calculation unit.

Detailed Description

[ example 1]

Fig. 1 is a system schematic diagram showing a vehicle control device according to embodiment 1. A vehicle is provided with: an engine 1 as a power source; a brake 20 (hereinafter, when a brake corresponding to a single wheel is shown, the brake is referred to as a right front wheel brake: 20FR, a left front wheel brake: 20FL, a right rear wheel brake: 20RR, and a left rear wheel brake: 20RL) for generating a braking torque by a frictional force for each wheel; and shock absorbers 3 (hereinafter, referred to as S/a. when S/a corresponding to a single wheel is indicated, referred to as a right front wheel S/a: 3FR, a left front wheel S/a: 3FL, a right rear wheel S/a: 3RR, and a left rear wheel S/a: 3RL) provided between each wheel and the vehicle body and capable of variably controlling damping force.

The engine 1 includes an engine controller (hereinafter also referred to as an engine control unit) 1a that controls torque output from the engine 1, and the engine controller 1a controls a throttle opening, a fuel injection amount, an ignition timing, and the like of the engine 1 to obtain a desired engine operating state (engine speed, engine output torque). The brake 20 generates a braking torque based on a hydraulic pressure supplied from a brake control unit 2 that can control the brake hydraulic pressure of each wheel according to the traveling state. The brake control means 2 includes a brake controller (hereinafter also referred to as a brake control unit) 2a that controls a braking torque generated by the brake 20, and causes the brakes 20 of the respective wheels to generate a desired hydraulic pressure by opening and closing operations of a plurality of electromagnetic valves using a master cylinder pressure generated by a brake pedal operation of a driver or a pump pressure generated by a built-in motor-driven pump as a hydraulic pressure source.

S/a3 is a damping force generating device that damps elastic movement of a coil spring provided between an unsprung portion (axle, wheel, etc.) and a sprung portion (vehicle body, etc.) of a vehicle, and is configured to be able to change a damping force by operation of an actuator. The S/a3 has a cylinder that seals fluid inside, a piston that moves inside the cylinder, and an orifice that controls fluid movement between fluid chambers formed above and below the piston. An orifice having a plurality of kinds of orifice diameters is formed in the piston, and when the S/a actuator is operated, an orifice corresponding to a control command is selected from the plurality of kinds of orifices. This enables generation of a damping force corresponding to the throttle bore. For example, if the orifice diameter is small, the movement of the piston is easily restricted, and therefore the damping force becomes high, and if the orifice diameter is large, the movement of the piston is not easily restricted, and therefore the damping force becomes small.

In addition to the selection of the throttle bore, for example, an electromagnetic control valve may be disposed in a communication path that fluidly connects the upper and lower portions of the piston, and the damping force may be set by controlling the opening/closing amount of the electromagnetic control valve, which is not particularly limited. The S/A3 has an S/a controller 3a that controls the damping force of the S/A3, and the damping force is controlled by operating the throttle aperture by the S/a actuator.

Further comprising: a wheel speed sensor 5 (hereinafter, referred to as a front right wheel speed: 5FR, a front left wheel speed: 5FL, a rear right wheel speed: 5RR, and a rear left wheel speed: 5RL when indicating a wheel speed corresponding to a single wheel) that detects a wheel speed of each wheel; an integrated sensor 6 that detects a front-rear acceleration, a yaw rate, and a lateral acceleration acting on a center of gravity point of the vehicle; a rotation angle sensor 7 that detects a steering angle that is a steering operation amount of a driver; a vehicle speed sensor 8 that detects a vehicle speed; an engine torque sensor 9 that detects an engine torque; an engine revolution sensor 10 that detects the number of engine revolutions; a master cylinder pressure sensor 11 that detects a master cylinder pressure; a brake switch 12, the brake switch 12 outputting an on-state signal when a brake pedal is operated; and an accelerator opening sensor 13 that detects an accelerator opening. Signals of these various sensors are input to the S/a controller 3 a. The placement of the integrated sensor 6 may be placed at the center of gravity of the vehicle or at other locations, and is not particularly limited as long as it can estimate various values at the center of gravity. Further, the yaw rate, the longitudinal acceleration, and the lateral acceleration may not necessarily be integrated, and may be independently detected.

Of the wheel speed sensors 5, the wheel speed sensors 5FL and 5FR for the right and left front wheels are attached to the front wheel hub, and detect the rotation of the axle as the wheel speed. On the other hand, wheel speed sensors 5RL and 5RR for the left and right rear wheels are attached to the differential gear, and detect rotation of the rear drive shaft as a wheel speed.

Fig. 2 is a control block diagram showing a control structure of a vehicle control device according to embodiment 1. In embodiment 1, the controller is composed of three controllers, i.e., an engine controller 1a, a brake controller 2a, and an S/a controller 3 a. The S/a controller 3a includes: a driver input control unit 31 that performs driver input control to achieve a desired vehicle posture in accordance with an operation (such as a steering operation, an accelerator pedal operation, and a brake pedal operation) by a driver; a running state estimation unit 32 that estimates a running state from detection values of various sensors; a sprung vibration damping control unit 33 that controls a sprung vibration state based on the estimated travel state; an unsprung vibration damping control unit 34 that controls the unsprung vibration state based on the estimated running state; and a damping force control unit 35 that determines a damping force to be set for S/a3 based on the absorber attitude control amount output from the driver input control unit 31, the sprung vibration damping control amount output from the sprung vibration damping control unit 33, and the unsprung vibration damping control amount output from the unsprung vibration damping control unit 34, and performs S/a damping force control.

In embodiment 1, the configuration in which three controllers are provided as the controllers is shown, but for example, the damping force control unit 35 may be eliminated from the S/a controller 3a to be the attitude control controller, and the damping force control unit 35 may be provided as the S/a controller to be four controllers, or each controller may be constituted by one integrated controller, and is not particularly limited. In embodiment 1, it is assumed that the control device of the vehicle of embodiment 1 is realized by using the engine controller and the brake controller in the existing vehicle as they are as the engine controller 1a and the brake controller 2a and by mounting the S/a controller 3a separately.

(Integrated Structure of control device for vehicle)

In the control device for a vehicle of embodiment 1, three actuators are used to control the state of vibration generated on the spring. At this time, since the respective controls control the sprung state, mutual interference becomes a problem. Further, the elements that can be controlled by the engine 1, the elements that can be controlled by the brake 20, and the elements that can be controlled by the S/a3 are different from each other, and how to combine them to control becomes a problem.

For example, the brake 20 can perform control of the pop-up motion and the pitch motion, but if both of these controls are performed, the feeling of deceleration is strong, and the driver is likely to be given an uncomfortable feeling. In addition, the S/A3 can control all of the roll motion, the bounce motion, and the pitch motion, but when the control is performed by the S/A3, the manufacturing cost of the S/A3 increases, and the damping force tends to increase, so that high-frequency vibration from the road surface side is easily input, and the driver still tends to feel uncomfortable. In other words, there is a trade-off relationship as follows: the control of the brake 20 does not cause deterioration of the high-frequency vibration but causes an increase in the feeling of deceleration, and the control of the S/a3 does not cause the feeling of deceleration but causes input of the high-frequency vibration.

Therefore, in the control device for a vehicle according to embodiment 1, in order to comprehensively determine these problems and realize a control device for a vehicle that is inexpensive but excellent in vibration damping capability by realizing a control structure that effectively utilizes points that are advantageous as respective control characteristics and mutually compensates for weak points, an overall control system is constructed mainly in consideration of the points listed below.

(1) The control amount of the S/a3 is suppressed by preferentially controlling the engine 1 and the brake 20.

(2) The sense of deceleration caused by the control of the brake 20 is eliminated by defining the control object motion of the brake 20 as pitch motion.

(3) The control amounts of the engine 1 and the brake 20 are limited to be lower than the control amounts that can be actually output, and output is performed, whereby the burden on the S/a3 is reduced, and the uncomfortable feeling caused by the control of the engine 1 and the brake 20 is suppressed.

(4) The ceiling control is performed by all the actuators. In this case, the skyhook control is realized with an inexpensive configuration by using wheel speed sensors mounted on all vehicles without using stroke sensors, sprung vertical acceleration sensors, and the like, which are generally required for skyhook control.

(5) When the sprung mass control of S/a3 is performed, scalar control (frequency-sensitive control) is newly introduced for input of high-frequency vibration that is difficult to handle in vector control such as skyhook control.

(6) The control state achieved by the S/a3 is appropriately selected in accordance with the running state, thereby providing an appropriate control state in accordance with the running condition.

The above is an outline of the overall control system configured in the embodiment. The contents of the individuals who realize them are explained in turn below.

(for driver input control part)

First, the driver input control unit will be described. The driver input control unit 31 includes an engine-side driver input control unit 31a for achieving the vehicle posture requested by the driver by torque control of the engine 1, and an S/a-side driver input control unit 31b for achieving the vehicle posture requested by the driver by damping force control of S/a 3. In the engine-side driver input control unit 31a, a yaw response control amount corresponding to a vehicle motion state desired by the driver is calculated from a contact load fluctuation suppression control amount for suppressing contact load fluctuations of the front wheels and the rear wheels and signals from the turning angle sensor 7 and the vehicle speed sensor 8, and is output to the engine control unit 1 a.

The S/a side driver input control unit 31b calculates a driver input damping force control amount corresponding to a vehicle motion state that the driver wants to achieve based on signals from the rotation angle sensor 7 and the vehicle speed sensor 8, and outputs the calculated amount to the damping force control unit 35. For example, if the vehicle head side of the vehicle is lifted during the turning of the driver, the field of view of the driver is likely to get off the road surface, so the damping forces of the four wheels are output as the driver input damping force control amounts to prevent the vehicle head from lifting in this case. The driver input damping force control amount for suppressing the roll generated during turning is also output.

(regarding roll control by S/A side driver input control)

Here, the roll suppression control by the S/a-side driver input control will be described. Fig. 3 is a control block diagram showing the configuration of the roll-rate restraining control of embodiment 1. The lateral acceleration estimating unit 31b1 estimates the lateral acceleration Yg from the front wheel turning angle δ f detected by the turning angle sensor 7 and the vehicle speed VSP detected by the vehicle speed sensor 8. The lateral acceleration Yg is calculated from the vehicle body plane model by the following formula.

Yg＝(VSP²/(1+A·VSP²))·δf

Here, a is a predetermined value.

The 90 ° phase lead component producing unit 31b2 differentiates the estimated lateral acceleration Yg and outputs a lateral acceleration differential value dYg. The first addition unit 31b4 adds the lateral acceleration Yg to the lateral acceleration differential dYg. The 90 ° phase retardation component producing unit 31b3 outputs a component f (Yg) obtained by retarding the phase of the estimated lateral acceleration Yg by 90 °. The second adding section 31b5 adds f (yg) to the value obtained by the addition in the first adding section 31b 4. The hilbert transform unit 31b6 calculates a scalar quantity of the envelope waveform based on the added value. The gain multiplier 31b7 multiplies the scalar quantity based on the envelope waveform by the gain, calculates the driver input attitude control amount for roll rate suppression control, and outputs the calculated amount to the damping force control unit 35.

Fig. 4 is a timing chart showing the envelope waveform forming process of the roll rate suppression control of embodiment 1. At time t1, when the driver starts steering, the roll rate starts to be gradually generated. At this time, the 90 ° phase advance is added to form an envelope waveform, and the driver input attitude control amount is calculated from a scalar quantity based on the envelope waveform, whereby the roll rate can be suppressed from being generated in the initial stage of steering. Next, at time t2, when the driver operates the steering hold state, the 90 ° phase advance component is not present, and the phase delay component f (yg) is added this time. At this time, even if the change of the roll rate itself is not so large in the normal turning state, a roll rate resonance component corresponding to the return shock of the roll is generated after the roll is once rolled. If the phase delay component f (yg) is not added, the damping force from time t2 to time t3 is set to a small value, which may cause the vehicle motion state to be unstable due to the roll-rate resonance component. In order to suppress the roll rate resonance component, a 90 ° phase retardation component f (yg) is added.

At time t3, when the driver transitions from the steering hold state to the straight-driving state, the lateral acceleration Yg becomes small, and the roll rate also converges to a small value. Here, since the damping force is reliably secured by the action of the 90 ° phase retardation component f (yg), the roll rate resonance component can be prevented from becoming unstable.

(concerning the running state estimating section)

Next, the traveling state estimating unit will be described. Fig. 5 is a control block diagram showing the configuration of the running state estimating unit according to embodiment 1. The running state estimating unit 32 of embodiment 1 basically calculates the stroke speed, the bounce rate, the roll rate, and the pitch rate of each wheel used for skyhook control by the sprung vibration damping control unit 33, which will be described later, based on the wheel speed detected by the wheel speed sensor 5. First, the values of the wheel speed sensors 5 of the respective wheels are input to the stroke speed calculation unit 321, and the sprung mass speed is calculated from the stroke speed of the respective wheels calculated by the stroke speed calculation unit 321.

Fig. 6 is a control block diagram showing the control contents of the stroke speed calculation unit in embodiment 1. The stroke speed calculation unit 321 is provided independently for each wheel, and the control block diagram shown in fig. 6 is a control block diagram focusing on a certain wheel. The stroke speed calculation unit 321 includes: a reference wheel speed calculation unit 300 that calculates two wheel speeds (a sprung reference wheel speed and an unsprung reference wheel speed) serving as references based on the value of the wheel speed sensor 5, the front wheel turning angle δ f and the rear wheel turning angle δ r detected by the turning angle sensor 7 (when a rear wheel turning device is provided, the actual rear wheel turning angle may be set to 0 when the rear wheel turning device is not provided), the vehicle lateral speed, and the actual yaw rate detected by the integrated sensor 6; a tire rotational vibration frequency calculation unit 321a that calculates a tire rotational vibration frequency from the calculated reference wheel speed; a deviation calculation unit 321b that calculates a deviation (wheel speed variation) between the sprung reference wheel speed and the wheel speed sensor value; a GEO conversion unit 321c that converts the deviation calculated by the deviation calculation unit 321b into a suspension stroke amount; a stroke speed correction unit 321d that corrects the converted stroke amount to a stroke speed; a signal processing unit 321e that applies a band elimination filter corresponding to the frequency calculated by the tire rotational vibration frequency calculation unit 321a to the value corrected by the stroke speed correction unit 321d to remove the tire rotational primary vibration component and calculate the final stroke speed; and a deviation calculation unit 321f that calculates a deviation (wheel speed variation) between the unsprung reference wheel speed and the wheel speed sensor value.

[ reference wheel speed calculation section ]

Here, the reference wheel speed calculation unit 300 will be described.

Fig. 7 is a block diagram showing the configuration of a reference wheel speed calculation unit according to embodiment 1, in which the reference wheel speed calculation unit 300 includes a sprung reference wheel speed calculation unit 300a and an unsprung reference wheel speed calculation unit 300b, the sprung reference wheel speed calculation unit 300a calculating an sprung reference wheel speed used for frequency-sensitive control in sprung attitude control described later, and the unsprung reference wheel speed calculation unit 300b calculating an unsprung reference wheel speed used for unsprung vibration damping control described later. Here, the reference wheel speed is a value obtained by removing various disturbances from each wheel speed. In other words, the difference between the wheel speed sensor value and the reference wheel speed is a value associated with a component that varies in accordance with the stroke caused by the bounce motion state, the roll motion state, the pitch motion state, or the unsprung vertical vibration of the vehicle body, and in the embodiment, the stroke speed is estimated from the difference.

The sprung reference wheel speed calculating unit 300a and the unsprung reference wheel speed calculating unit 300b have the same configuration except for the rear wheel speed estimating units 305a, 305b, and therefore will be described collectively.

The plane motion component extraction unit 301 calculates a first wheel speed V0, which is a reference wheel speed of each wheel, from the vehicle body plane model using the wheel speed sensor value as an input. Here, the wheel speed sensor value detected by the wheel speed sensor 5 is ω (rad/s), the actual rotation angle of the front wheel detected by the rotation angle sensor 7 is δ f (rad), the actual rotation angle of the rear wheel is δ r (rad), the vehicle lateral speed is Vx, the yaw rate detected by the integrated sensor 6 is γ (rad/s), the vehicle body speed estimated from the calculated reference wheel speed ω 0 is V (m/s), the reference wheel speeds to be calculated are VFL, VFR, VRL, VRR, the tread of the front wheel is Tf, the tread of the rear wheel is Tr, the distance from the vehicle center of gravity position to the front wheel is Lf, and the distance from the vehicle center of gravity position to the rear wheel is Lr. Using the above data, a vehicle body plane model is expressed as follows.

(formula 1)

VFL=(V-Tf/2·γ)cosδf+(Vx+Lf·γ)sinδf

VFR＝(V+Tf/2·γ)cosδf+(Vx+Lf·γ)sinδf

VRL＝(V-Tr/2·γ)cosδr+(Vx-Lr·γ)sinδr

VRR＝(V+Tr/2·γ)cosδr+(Vx-Lr·γ)sinδr

When the vehicle is assumed to be in a normal running state in which the vehicle is not slipping, the vehicle body lateral velocity Vx only needs to be input with 0. The expression is as follows when values based on V are rewritten in the respective expressions for this. In the rewriting, V is described as values corresponding to the respective wheels as V0FL, V0FR, V0RL, and V0RR (corresponding to the first wheel speed).

(formula 2)

V0FL＝{VFL-LF·γsinδf}/cosδf+Tf/2·γ

V0FR＝{VFR-Lf·γsinδf}/cosδf-Tf/2·γ

V0RL＝{VRL+Lr·γsinδr}/cosδr+Tr/2·γ

V0RR＝{VRR+Lf·γsinδf}/cosδr-Tr/2·γ

The sprung rear wheel speed estimating unit 305a and the unsprung rear wheel speed estimating unit 305b calculate an estimated first wheel speed of the rear wheel by delaying the first wheel speed of the front wheel, select one of the estimated first wheel speed and the first wheel speed of the rear wheel output from the plane motion component extracting unit 301 from the vehicle speed, and output the selected one as the first wheel speed of the rear wheel. An estimated first wheel speed of the left rear wheel is calculated from the first wheel speed of the left front wheel, and an estimated first wheel speed of the right rear wheel is calculated from the first wheel speed of the right front wheel. The sprung rear wheel speed estimating unit 305a and the unsprung rear wheel speed estimating unit 305b store the first wheel speed of the front wheel in the memory when a predetermined condition is satisfied, and output the first wheel speed of the front wheel held in the memory as the first wheel speed of the rear wheel instead of the first wheel speed of the rear wheel output from the planar motion component extracting unit 301 when the delay time has elapsed. On the other hand, when the predetermined condition is not satisfied, the first wheel speed of the front wheel is not stored. Here, the delay time is a value obtained by dividing the wheel base by the vehicle speed. Further, the delay time is calculated by increasing the yaw rate at the time of turning (yaw rate ≠ 0).

When the predetermined condition is satisfied with both of the following conditions 1 and 2 in the sprung rear wheel speed estimating unit 305a, the predetermined condition is satisfied with the following condition 1 in the unsprung rear wheel speed estimating unit 305 b.

1. The vehicle speed is above the low vehicle speed threshold V1 and less than the high vehicle speed threshold V2

2. Implementing frequency-sensitive control as sprung attitude control

The low vehicle speed threshold V1 is set to a vehicle speed slightly higher than a vehicle speed at which the magnitude of information stored when the vehicle is traveling at a fixed vehicle speed exceeds a predetermined upper limit of the buffer memory. The high vehicle speed threshold V2 is set to a vehicle speed slightly lower than a speed obtained by dividing the wheel base by the sampling period of the wheel speed sensor value.

In the embodiment, the sprung rear wheel speed estimating unit 305a and the unsprung rear wheel speed estimating unit 305b are provided between the planar motion extracting unit 301 and the road surface disturbance removing unit, but may be provided in the front stage of the planar motion component extracting unit 301.

Fig. 8 is a flowchart showing a rear wheel speed estimation process by the sprung rear wheel speed estimation unit 305a, where (a) is a flow of a process of storing the first wheel speed of the front wheel in the memory, and (b) is a flow of a process of outputting the first wheel speed of the rear wheel. The two processes are repeatedly performed independently in each sampling period.

In step S61, a first wheel speed of the front wheel is input.

In step S62, it is determined whether or not the vehicle speed when the first wheel speed of the front wheel is input in step S61 is equal to or higher than the low vehicle speed threshold V1 and lower than the high vehicle speed threshold V2, and if yes, the routine proceeds to step S63, and if no, the routine returns.

In step S63, it is determined whether or not frequency-dependent damping control is performed as sprung vibration damping control, and if yes, the routine proceeds to step S64, and if no, the routine returns.

In step S64, the wheel base is divided by the vehicle speed to calculate the delay time (the first wheel speed of the front wheel input in step S61 is output after several cycles). At this time, the yaw rate is increased while turning.

In step S65, the first wheel speed and the delay time of the front wheel input in step S61 are stored as delay information in a memory.

In step S66, it is determined whether the first wheel speed of the front wheel output in the sampling period is stored in the memory, and in the case of yes, the routine proceeds to step S67, and in the case of no, the routine proceeds to step S68.

In step S68, the first wheel speed of the front wheel stored in the memory is output as the first wheel speed of the rear wheel.

In step S69, the first wheel speed of the rear wheel input from the planar motion component extraction unit 301 is output.

In the rear wheel speed estimation process of the sprung rear wheel speed estimation unit 305a, when the vehicle speed is less than the low vehicle speed threshold value V1, a buffer overflow (buffer overflow) of the memory occurs, and therefore estimation of the rear wheel is prohibited. Further, when the vehicle speed is equal to or higher than the high vehicle speed threshold value V2, the estimation of the rear wheels is prohibited because an unrealizable delay time is set. Further, during reverse, the wheel speed of the rear wheel cannot be estimated using the wheel speed sensor value of the front wheel, and therefore estimation of the rear wheel is prohibited. Further, when the skyhook control is performed as the sprung vibration damping control, the vibration damping performance may be deteriorated, and therefore, estimation of the rear wheels is prohibited.

Note that the rear wheel speed estimation process of the unsprung rear wheel speed estimation unit 305b is the same as the process after the process of step S63 is removed from fig. 8 (a), and therefore, the description thereof is omitted. The wheel speed of the unsprung rear wheel vehicle is not used for sprung vibration damping control, and therefore, even when skyhook control is performed, no influence is given.

The roll disturbance removing unit 302 receives the first wheel speed V0 as an input, and calculates second wheel speeds V0F and V0R as reference wheel speeds of front and rear wheels from a vehicle body forward view model. The vehicle body front view model is a model that removes a wheel speed difference generated due to a rolling motion generated around a rolling rotation center on a vertical line passing through a center of gravity point of a vehicle when the vehicle is viewed from the front, and is expressed by the following equation.

V0F＝(V0FL+V0FR)/2

V0R＝(V0RL+V0RR)/2

Thus, the second wheel speeds V0F, V0R from which the roll-based disturbance is removed can be obtained.

The pitch disturbance removing unit 303 receives the second wheel speeds V0F and V0R as inputs, and calculates third wheel speeds VbFL, VbFR, VbRL, and VbRR, which are reference wheel speeds of all the wheels, from the vehicle body side view model. Here, the vehicle body side view model is a model in which a wheel speed difference generated by a pitch motion generated around a pitch rotation center on a vertical line passing through a center of gravity point of the vehicle is removed when the vehicle is viewed from a lateral direction, and is expressed by the following equation.

(formula 3)

VbFL＝VbFR＝VbRL＝VbRR＝{Lr/(Lf+Lr)}V0F+{Lf/(Lf+Lr)}V0R

The reference wheel speed redistributing unit 304 substitutes VbFL (VbFR) and VbRL (VbRR) into V of the vehicle body plane model shown in equation 1, calculates final reference wheel speeds VFL, VFR, VRL, and VRR of the respective wheels, and divides the calculated final reference wheel speeds VFL, VFR, VRL, and VRR by the tire radius r0 to calculate the sprung reference wheel speed ω 0.

When the reference wheel speed ω 0 of each wheel is calculated by the above-described processing, a deviation between the reference wheel speed ω 0 and the wheel speed sensor value, which is a variation in wheel speed caused by the suspension stroke, is calculated and converted into the stroke speed Vz _ s. Basically, the suspension not only generates a stroke in the up-down direction when holding each wheel, but also the wheel rotation center moves forward and backward with the stroke, and the axle itself is also inclined, generating a rotation angle difference with the wheel. Since the wheel speed changes with the forward and backward movement, the deviation between the reference wheel speed and the wheel speed sensor value can be extracted as the variation accompanying the stroke. The degree of fluctuation to be generated may be appropriately set according to the suspension geometry.

Here, since the wheel speed sensors 5FL and 5FR of the front wheels are attached to the axle (front hub), the change in the wheel speed sensor value with respect to the inclination of the axle caused by the stroke of the suspension is large, whereas since the wheel speed sensors 5RL and 5RR of the rear wheels are attached to the differential gear, the change in the wheel speed sensor value with respect to the inclination of the axle caused by the stroke of the suspension is small, and the inclination of the axle is hardly reflected in the change in the wheel speed sensor value. That is, the wheel speed sensors 5RL, 5RR of the rear wheels have low sensitivity to the inclination of the axle that accompanies the stroke of the suspension. Therefore, when the reference wheel speed is obtained using the wheel speed sensor values of the wheel speed sensors 5RL, 5RR of the rear wheels, the accuracy of estimation of the stroke speed is degraded, resulting in deterioration of vibration damping performance.

Therefore, in embodiment 1, the wheel speed of the rear wheel is estimated by delaying the wheel speed detected by the wheel speed sensors 5FL and 5FR for the front wheels having high sensitivity with respect to the inclination of the axle due to the stroke of the suspension, so that the accuracy of estimating the stroke speed is improved, and the deterioration of the vibration damping performance is suppressed.

When the stroke speeds Vz _ sFL, Vz _ sFR, Vz _ sRL, and Vz _ sRR of the wheels are calculated by the above processing in the stroke speed calculation unit 321, the sprung mass speed calculation unit 322 calculates the bounce rate, roll rate, and pitch rate for skyhook control.

(about estimation model)

The skyhook control is a control in which a damping force is set according to the relationship between the stroke speed of the S/a3 and the sprung speed, and the sprung attitude is controlled to achieve a flat traveling state. Here, in order to achieve sprung attitude control by skyhook control, it is necessary to feed back sprung velocity. Since the value that can be currently detected by the wheel speed sensor 5 is the stroke speed and the sprung mass does not include a vertical acceleration sensor or the like, it is necessary to estimate the sprung mass speed using an estimation model. Next, the problem of the estimation model and the model structure to be used will be described.

Fig. 9 is a schematic diagram showing a vehicle body vibration model. Fig. 9 (a) is a model of a vehicle (hereinafter, referred to as a conventional vehicle) having an S/a with a fixed damping force, and fig. 9 (b) is a model of a vehicle having an S/a with a variable damping force and performing a skyhook control. In fig. 9, Ms denotes an sprung mass, Mu denotes an unsprung mass, Ks denotes an elastic coefficient of a coil spring, Cs denotes a damping coefficient of S/a, Ku denotes an unsprung (tire) elastic coefficient, Cu denotes an unsprung (tire) damping coefficient, and Cv denotes a variable damping coefficient. In addition, z2 represents an sprung position, z1 represents an unsprung position, and z0 represents a road surface position.

In the case of using the conventional vehicle model shown in fig. 9 (a), the equation of motion for the spring is expressed as follows. Further, the first derivative (i.e., velocity) of z1 is represented by dz1, and the second derivative (i.e., acceleration) is represented by ddz 1.

(estimation formula 1)

Ms·ddz2＝-Ks(z2-z1)-Cs(dz2-dz1)

The relational expression is expressed as follows when the relational expression is subjected to laplace transform and then arranged.

(estimation formula 2)

dz2＝-(1/Ms)·(1/s²)·(Cs·s+Ks)(dz2-dz1)

Here, dz2-dz1 are stroke velocities (Vz _ sFL, Vz _ sFR, Vz _ sRL, Vz _ sRR), and therefore the sprung mass velocity can be calculated from the stroke velocity. However, the following problems arise: when the damping force is changed by the skyhook control, the estimation accuracy is significantly degraded, so that a large attitude control force (damping force change) cannot be provided if it is a conventional vehicle model.

Therefore, it is considered to use a vehicle model controlled by a sunroof as shown in fig. 9 (b). Basically, the damping force is changed when the movement speed of the piston of the S/a3 is limited according to the change of the suspension stroke. Since the semi-active S/a3 that cannot actively move the piston in a desired direction is used, the sprung mass velocity is obtained using the semi-active skyhook model as follows.

(estimation formula 3)

dz2＝-(1/Ms)·(1/s²)·{(Cs+Cv)·s+Ks}(dz2-dz1)

Wherein,

when dz2 ≧ O (dz2-dz1) ≧ O, Cv ═ Csky [ { dz2/(dz2-dz1) }

When dz2 · (dz2-dz1) < O, Cv ═ O

That is, Cv is a discontinuous value.

When it is considered that the sprung mass velocity is estimated using a simple filter, if the model is a semi-active skyhook model, each variable corresponds to a filter coefficient, and the analog differential term { (Cs + Cv) · s + Ks } includes a discontinuous variable damping coefficient Cv, so that the filter response becomes unstable, and appropriate estimation accuracy cannot be obtained. Especially when the filter response becomes unstable, resulting in phase shifts. If the phase of the sprung velocity and the sign lose correspondence, skyhook control cannot be achieved. Therefore, even when the semi-active S/a3 is used, the sprung mass velocity is estimated using an active skyhook model that can directly use the stable Csky, regardless of the sign relationship between the sprung mass velocity and the stroke velocity. When the sprung velocity is found using the active skyhook model, it is expressed as follows.

(estimation formula 4)

dz2＝-(1/s)·{1/(s+Csky/Ms)}·{(Cs/Ms)s+(Ks/Ms)}(dz2-dz1)

In this case, no discontinuity is generated in the analog differential term { (Cs/Ms) s + (Ks/Ms) }, and the term of {1/(s + Csky/Ms) } can be constituted by a low-pass filter. Therefore, the filter response is stable, and appropriate estimation accuracy can be obtained. In addition, even if an active ceiling model is used, only semi-active control is actually possible, and thus the controllable area is reduced by half. Therefore, although the magnitude of the estimated sprung mass velocity is smaller than the actual velocity in the frequency band below the sprung mass resonance, the phase is most important in skyhook control, and since skyhook control can be achieved as long as the correspondence between the phase and the sign can be maintained, the magnitude of the sprung mass velocity can be adjusted by other coefficients and the like, there is no problem.

From the above relationship, it can be understood that the sprung mass velocity can be estimated by knowing the stroke velocity of each wheel. Next, since the actual vehicle is not one wheel but four wheels, a case where the on-spring state pattern is estimated by decomposing into a roll rate, a pitch rate, and a bounce rate using the stroke speed of each of these wheels is examined. In the case where the above three components are currently calculated from the stroke speeds of four wheels, the solution is uncertain if the corresponding component is missing one, and therefore a torsion rate representing the motion of the diagonal wheel is introduced. When the bounce term of the stroke amount is xsB, the roll term is xsR, the pitch term is xsP, the torsion term is xsW, and the stroke amounts corresponding to Vz _ sFL, Vz _ sFR, Vz _ sRL, Vz _ sRR are z _ sFL, z _ sFR, z _ sRL, z _ sRR, the following equation is satisfied.

(formula 1)

Based on the above relational expression, the following expressions represent the differential dxsB of xsB, xsR, xsP, xsW, and the like.

dxsB＝1/4(Vz_sFL+Vz_sFR+Vz_sRL+Vz_sRR)

dxsR＝1/4(Vz_sFL-Vz_sFR+Vz_sRL-Vz_sRR)

dxsP＝1/4(-Vz_sFL-Vz_sFR+Vz_sRL+Vz_sRR)

dxsW＝1/4(-Vz_sFL+Vz_sFR+Vz_sRL-Vz_sRR)

Here, since the relationship between the sprung mass velocity and the stroke velocity is obtained from the above-described estimation equation 4, the section of (1/s) {1/(s + Csky/Ms) } { (Cs/Ms) s + (Ks/Ms) } in the estimation equation 4 is denoted by G, and when values obtained by considering the modal parameters (CskyB, CskyR, CskyP, CsB, CsR, CsP, KsB, KsR, KsP) corresponding to the bounce term, the roll term, and the pitch term of Csky, Cs, and Ks, respectively, are denoted by GB, GR, and GP, the bounce rates are denoted by dB, the roll rate is denoted by dR, and the pitch rate is denoted by dP, dB, dR, and dP can be calculated as the following values.

dB＝GB·dxsB

dR＝GR·dxsR

dP＝GP·dxsP

Based on the above, the actual state estimation on the spring in the vehicle can be achieved based on the stroke speed of each wheel.

(sprung vibration damping control unit)

Next, the structure of the sprung vibration damping control unit 33 will be described. As shown in fig. 2, the sprung vibration damping control unit 33 includes a skyhook control unit 33a that performs attitude control based on the sprung velocity estimation value, and a frequency-sensitive control unit 33b that suppresses sprung vibration based on the road surface input frequency.

[ Structure of ceiling control section ]

The vehicle control device of embodiment 1 includes three actuators, i.e., the engine 1, the brake 20, and the S/a3, as actuators for achieving the sprung attitude control. The skyhook control unit 33a controls the S/a3 to control the three of the bounce rate, roll rate, and pitch rate, controls the bounce rate and pitch rate of the engine 1, and controls the pitch rate of the brake 20. Here, in order to control the sprung mass state by distributing control amounts to a plurality of actuators having different actions, it is necessary to use a control amount common to the respective actuators. In embodiment 1, the control amount for each actuator can be determined by using the sprung mass velocity estimated by the travel state estimating unit 32 described above.

The ceiling control amount in the bounce direction is

FB＝CskyB·dB，

The ceiling control amount in the roll direction is

FR＝CskyR·dR，

The ceiling control amount in the pitch direction is

FP＝CskyP·dP。

FB is sent to the engine 1 and S/A3 as the bounce attitude control amount, FR is control performed only in S/A3, and is thus sent to the damping force control section 35 as the roll attitude control amount.

Next, the canopy control amount FP in the pitch direction will be described. The pitch control is performed by the engine 1, the brake 20, and the S/a 3.

Fig. 10 is a control block diagram showing the process of calculating the control amount of each actuator when pitch control is performed according to embodiment 1. The ceiling control unit 33a includes: a first target attitude control amount calculation unit 331 that calculates a target pitch rate that is a first target attitude control amount that is a control amount that can be used in common for all the actuators; an engine posture control amount calculation unit 332 that calculates an engine posture control amount achieved by the engine 1; a brake attitude control amount calculation unit 334 that calculates a brake attitude control amount achieved by the brake 20; and an S/a attitude control amount calculation unit 336 for calculating the S/a attitude control amount achieved by the S/a 3.

In the skyhook control of the present system, since the first priority is given to the operation to suppress the pitch rate, the first target attitude control amount calculation unit 331 directly outputs the pitch rate (hereinafter, this pitch rate is referred to as a first target attitude control amount). The engine posture control amount calculation unit 332 calculates an engine posture control amount, which is a control amount that the engine 1 can achieve, based on the first target posture control amount that is input.

In the engine posture control amount calculation unit 332, a limit value for limiting the engine torque control amount according to the engine posture control amount is set so as not to give a sense of discomfort to the driver. Thus, the engine torque control amount is limited to be within a predetermined longitudinal acceleration range when converted into the longitudinal acceleration. Therefore, the engine torque control amount is calculated from the first target attitude control amount, and when a value equal to or larger than the limit value is calculated, the skyhook control amount (a value obtained by multiplying the pitch rate suppressed by the engine 1 by CskyP, hereinafter referred to as the engine attitude control amount) of the pitch rate achievable according to the limit value is output. At this time, the value converted into the pitch rate by the conversion unit 332a is output to the second target attitude control amount calculation unit 333, which will be described later. The engine control unit 1a calculates an engine torque control amount based on the engine posture control amount corresponding to the limit value, and outputs the engine torque control amount to the engine 1.

The second target attitude control amount calculation unit 333 calculates a second target attitude control amount, which is a deviation between the first target attitude control amount and a value obtained by converting the engine attitude control amount into the pitch rate in the conversion unit 332a, and outputs the second target attitude control amount to the brake attitude control amount calculation unit 334. In the brake attitude control amount calculation unit 334, a limit value for limiting the brake torque control amount is set (the limit value will be described in detail later) so as not to give a sense of discomfort to the driver, as in the case of the engine 1.

Thus, the braking torque control amount is limited so as to fall within a predetermined longitudinal acceleration range (a limit value obtained from the uncomfortable feeling of the occupant, the life of the actuator, and the like) when converted into the longitudinal acceleration. Therefore, the brake attitude control amount is calculated from the second target attitude control amount, and when a value equal to or larger than the limit value is calculated, a pitch rate suppression amount (hereinafter referred to as brake attitude control amount) that can be achieved according to the limit value is output. At this time, the value converted into the pitch rate by the conversion unit 3344 is output to the third target attitude control amount calculation unit 335, which will be described later. The brake control unit 2a calculates a braking torque control amount (or deceleration) based on the brake attitude control amount corresponding to the limit value, and outputs the braking torque control amount (or deceleration) to the brake control member 2.

The third target attitude control amount calculation unit 335 calculates a third target attitude control amount, which is a deviation between the second target attitude control amount and the brake attitude control amount, and outputs the calculated third target attitude control amount to the S/a attitude control amount calculation unit 336. The S/a attitude control amount calculation unit 336 outputs a pitch attitude control amount corresponding to the third target attitude control amount.

The damping force control unit 35 calculates a damping force control amount from the bounce attitude control amount, the roll attitude control amount, and the pitch attitude control amount (hereinafter, these are collectively referred to as "S/a attitude control amount"), and outputs the damping force control amount to the S/a 3.

[ brake pitch control ]

Here, the brake pitch control is explained. In general, the brake 20 can control both the bounce and the pitch, and therefore, it can be said that both controls are preferable. However, in the bounce control of the brake 20, since the braking force is generated simultaneously for the four wheels, it is difficult to obtain the control effect even in the direction of the control priority from high to low, but the feeling of deceleration is strong, and there is a tendency that the driver feels a sense of discomfort. Therefore, the brake 20 is configured to be dedicated to the pitch control. Fig. 11 is a control block diagram showing the brake-pitch control according to embodiment 1. When the mass of the vehicle body is m, the braking force of the front wheels is BFf, the braking force of the rear wheels is BFr, the height between the center of gravity of the vehicle and the road surface is Hcg, the acceleration of the vehicle is a, the pitch moment is Mp, and the pitch rate is Vp, the following relational expression is established.

BFf+BFr＝m·a

m·a·Hcg＝Mp

Mp＝(BFf+BFr)·Hcg

Here, if the braking force is provided when the pitch rate Vp is positive, that is, the front wheel side sinks, the front wheel side is caused to sink further, the pitch motion is promoted, and therefore the braking force is not applied in this case. On the other hand, when the pitch rate Vp is negative, that is, when the front wheel side is lifted, the brake pitch moment provides a braking force to suppress the lifting of the front wheel side. This ensures the field of view of the driver and facilitates the viewing forward, thereby contributing to an improvement in the feeling of security and flatness. In light of the above, it is desirable to,

when Vp is greater than 0 (front wheel sinking), a control quantity of Mp being 0 is provided,

when Vp is less than or equal to 0 (front wheel lift), a control amount of Mp ═ CskyP · Vp is provided.

Thus, since the braking torque is generated only when the front end side of the vehicle body is raised, the generated deceleration can be reduced as compared with a case where the braking torque is generated both when the vehicle body is raised and when the vehicle body is lowered. Further, since the actuator operating frequency can be halved, a low-cost actuator can be used.

Based on the above relationship, the brake attitude control amount calculation unit 334 includes the following control frames. The insensitive area processing sign determination unit 3341 determines the sign of the input pitch rate Vp, and when the sign is positive, since control is not necessary, 0 is output to the deceleration feeling reduction processing unit 3342, and when the sign is negative, control is possible, and a pitch rate signal is output to the deceleration feeling reduction processing unit 3342.

[ deceleration feeling reduction treatment ]

Next, the deceleration feeling reduction processing is described. This processing corresponds to the limitation by the limit value performed in the brake attitude control amount calculation unit 334. The square processing unit 3342a squares the pitch rate signal. This reverses the sign and smoothes the rise in the control force. The pitch rate squared damping torque calculation section 3342b calculates the pitch torque Mp by multiplying the skyhook gain CskyP considering the squared pitch term by the pitch rate obtained by the squaring. The target deceleration calculating section 3342c calculates the target deceleration by dividing the pitch moment Mp by the mass m and the height Hcg between the center of gravity of the vehicle and the road surface.

The jerk threshold limiting unit 3342d determines whether or not the calculated change rate of the target deceleration, that is, whether or not the jerk is within a range of a deceleration jerk threshold and a removal jerk threshold set in advance and whether or not the target deceleration is within a range of front and rear acceleration limit values, corrects the target deceleration to a value within the range of the jerk threshold when any one of the thresholds is exceeded, and sets the target deceleration within the limit value when the target deceleration exceeds the limit value. This makes it possible to generate deceleration without giving an uncomfortable feeling to the driver.

The target pitching moment converting unit 3343 calculates a target pitching moment by multiplying the mass m and the height Hcg by the target deceleration limited by the jerk threshold limiting unit 3342d, and outputs the target pitching moment to the brake control unit 2a and the target pitching rate converting unit 3344. The target pitch rate conversion unit 3344 divides the target pitch moment by the skyhook gain CskyP of the pitch term to convert the divided moment into a target pitch rate (corresponding to the brake attitude control amount), and outputs the converted rate to the third target attitude control amount calculation unit 335.

As described above, the pitch rate is calculated as the first target attitude control amount, the engine attitude control amount is calculated as the second target attitude control amount, the brake attitude control amount is calculated as the second target attitude control amount, which is the deviation between the first target attitude control amount and the engine attitude control amount, and the S/a attitude control amount is calculated as the third target attitude control amount, which is the deviation between the second attitude control amount and the brake attitude control amount. Thus, the amount of pitch rate control by the S/A3 can be reduced by controlling the engine 1 and the brake 20, and therefore the controllable region of the S/A3 can be made relatively narrow, and sprung attitude control can be achieved by the inexpensive S/A3.

In addition, when the control amount of the S/a3 is increased, basically the damping force increases. Since the damping force is increased by the suspension characteristics that are hard, when high-frequency vibration is input from the road surface side, the high-frequency input is easily transmitted, and the comfort of the passenger is impaired (hereinafter, referred to as deterioration of the high-frequency vibration characteristics). In contrast, the control amount of the S/a3 can be reduced by suppressing the pitch rate by the actuator such as the engine 1 and the brake 20, which does not affect the vibration transmission characteristics due to road surface input, and deterioration of the high-frequency vibration characteristics can be avoided. The above effects can be obtained by determining the control amount of the engine 1 before S/A3 and the control amount of the brake 2 before S/A3.

[ frequency induction control section ]

Next, a frequency induction control process in the sprung vibration damping control unit will be described. In embodiment 1, the sprung mass speed is estimated basically from the detection value of the wheel speed sensor 5, and the sprung mass vibration damping control is achieved by performing skyhook control based on the sprung mass speed. However, there are cases where it is considered that the wheel speed sensor 5 cannot sufficiently ensure the estimation accuracy, and it is desired to actively ensure a comfortable running state (a softer ride feeling than a vehicle body flatness feeling) depending on the running condition and the intention of the driver. In this case, as in skyhook control, since there is a case where the phase is slightly shifted in vector control in which the sign relationship (phase, etc.) between the stroke velocity and the sprung mass velocity is important, and it is difficult to perform appropriate control, it is assumed that sprung mass vibration damping control corresponding to a scalar quantity of vibration characteristics, that is, frequency-sensitive control is introduced.

Fig. 12 is a graph in which the wheel speed frequency characteristic detected by the wheel speed sensor and the stroke frequency characteristic of the stroke sensor not mounted in the embodiment are plotted at the same time. Here, the frequency characteristic is a characteristic in which the magnitude of the amplitude with respect to the frequency is taken as a scalar quantity on the vertical axis. When the frequency component of the wheel speed sensor 5 is compared with the frequency component of the stroke sensor, it can be understood that approximately the same scalar quantity is obtained from the sprung resonance frequency component to the unsprung resonance frequency component. Therefore, the damping force is set based on the frequency characteristic in the detection value of the wheel speed sensor 5. Here, the region where the sprung resonance frequency component exists is defined as a flight region (0.5Hz to 3Hz) as a frequency region where the passenger feels as if the passenger is thrown into the air due to the vibration of the entire passenger's body, in other words, the feeling of the passenger's gravitational acceleration is reduced, the region between the sprung resonance frequency component and the unsprung resonance frequency component is defined as a bounce region (3Hz to 6Hz) where the human body feels like pitching when the rider is running (trot) without feeling the reduction of the gravitational acceleration, in other words, the up-and-down motion that the entire body can follow, the region in which the unsprung resonance frequency component is present is defined as a vibration region (6Hz to 23Hz) as a frequency region in which slight vibration is transmitted to a part of the body such as the thigh of the passenger, although the region is not moving up and down to the extent that the mass of the human body can follow.

Fig. 13 is a control block diagram showing frequency-dependent control in sprung vibration damping control according to embodiment 1. The band elimination filter 350 cuts off noise other than the vibration component used for the present control in the wheel speed sensor value. The predetermined frequency region dividing unit 351 divides the frequency region into a vacant region, a jitter region, and a jitter region. The hilbert transform processing unit 352 hilbert transforms each divided frequency band into a scalar quantity of amplitude (specifically, an area calculated from the amplitude and the frequency band) based on the frequency.

The vehicle vibration system weight setting unit 353 sets the weight at which the vibration of each frequency band in the empty space region, the bouncing region, and the shake region is actually transmitted to the vehicle. The human perception weight setting unit 354 sets the weight with which the vibration of each frequency band of the empty space region, the pulsating region, and the jitter region is transmitted to the passenger.

Here, setting of human sensory weight is explained. Fig. 14 is a correlation diagram showing human sensory characteristics with respect to frequency. As shown in fig. 14, in the empty region, which is a low-frequency region, the sensitivity of the passenger with respect to the frequency is low, and the sensitivity gradually increases as the passenger moves to a high-frequency region. In addition, a high frequency region above the jitter region is difficult to be delivered to the passenger. From the above, the human perception weight Wf of the empty region is set to 0.17, the human perception weight Wh of the jumping region is set to 0.34 larger than Wf, and the human perception weight Wb of the shaking region is set to 0.38 larger than Wf and Wh. This can further improve the correlation between the scalar quantity of each frequency band and the vibration actually propagated to the passenger. The two weighting factors may be appropriately changed according to the concept of the vehicle and the preference of the passenger.

Weight determining section 355 calculates the ratio of the weight of each frequency band among the weights of the frequency bands. When the weight of the empty region is a, the weight of the jitter region is b, and the weight of the jitter region is c, the weight coefficient of the empty region is (a/(a + b + c)), the weight coefficient of the jitter region is (b/(a + b + c), and the weight coefficient of the jitter region is (c/(a + b + c)).

The scalar operation unit 356 multiplies the weight calculated by the weight determination unit 355 by the scalar of each frequency band calculated by the hilbert transform processing unit 352, and outputs the final scalar. The processing up to now is performed for the wheel speed sensor value of each wheel.

The maximum value selector 357 selects the maximum value from the final scalars calculated for the four wheels. The lower 0.01 is set to avoid the denominator being 0 because the total of the maximum values is set as the denominator in the following processing. The ratio calculation unit 358 calculates the ratio by using the sum of the scalar maximum values of the frequency bands as a denominator and the scalar maximum value of the frequency band corresponding to the empty region as a numerator. In other words, the mixing ratio (hereinafter, simply referred to as the ratio) of the empty region included in all the vibration components is calculated. The sprung resonance filter 359 performs filtering processing of the sprung resonance frequency of about 1.2Hz with respect to the calculated ratio, and extracts a component indicating the sprung resonance frequency band of the empty region from the calculated ratio. In other words, since the flight area exists around 1.2Hz, the ratio of the area is considered to vary around 1.2 Hz. Then, the finally extracted ratio is output to the damping force control unit 35, and a frequency-dependent damping force control amount corresponding to the ratio is output.

Fig. 15 is a characteristic diagram showing the relationship between the vibration mixing ratio in the empty space region and the damping force in the frequency-sensitive control of example 1. As shown in fig. 15, the vibration level of the sprung resonance is reduced by setting the damping force high when the ratio of the empty region is large. In this case, even if the damping force is set high, the ratio of the bounce region to the shake region is small, and therefore vibrations such as high-frequency vibrations or slight motions are not transmitted to the passenger. On the other hand, when the percentage of the empty region is small, the damping force is set low, so that the vibration transmission characteristics equal to or higher than the sprung resonance are reduced, the high-frequency vibration is suppressed, and a smooth ride feeling can be obtained.

Here, the advantage of the frequency induction control in the case of comparing the frequency induction control with the skyhook control will be described. Fig. 16 is a diagram showing a wheel speed frequency characteristic detected by the wheel speed sensor 5 under a certain running condition. This is a characteristic exhibited when the vehicle travels on a road surface in which small irregularities are continuous, such as a slate road. When skyhook control is performed while traveling on a road surface showing such characteristics, since the damping force is determined by the peak value of the amplitude in the skyhook control, if the phase estimation becomes poor with respect to the input of the high-frequency vibration, a very high damping force is set at an incorrect timing, and there is a problem that the high-frequency vibration deteriorates.

On the other hand, when control is performed based on a scalar quantity rather than a vector quantity as in the frequency-sensitive control, the ratio of the empty region in the road surface as shown in fig. 16 is small, and therefore a low damping force is set. Thus, even when the amplitude of the vibration in the dither region is large, the vibration transmission characteristics are sufficiently reduced, and therefore, the deterioration of the high-frequency vibration can be avoided. Based on the above, for example, in a region in which control is difficult due to deterioration of phase estimation accuracy even if skyhook control is performed by providing an expensive sensor or the like, high-frequency vibration can be suppressed by frequency induction control based on a scalar quantity.

(unsprung vibration damping control section)

Next, the structure of the unsprung vibration damping control portion will be described. As illustrated in the conventional vehicle of fig. 9 (a), since the tire also has an elastic coefficient and a damping coefficient, a resonance frequency band exists. However, since the mass of the tire is small compared to the sprung mass and the elastic coefficient is also high, the tire exists on a higher frequency side than the sprung resonance. The unsprung tire moves in a pitch due to the unsprung resonance component, and thus the ground contact performance may be deteriorated. In addition, the unsprung mass may also give the passengers a sense of discomfort. Therefore, in order to suppress the disturbance due to the unsprung resonance, a damping force corresponding to the unsprung resonance component is set.

Fig. 17 is a block diagram showing a control structure of the unsprung vibration damping control in embodiment 1. The unsprung resonance component extraction unit 341 extracts an unsprung resonance component by applying a band-pass filter to the variation in the wheel speed output from the deviation calculation unit 321b in the running state estimation unit 32. The unsprung resonance component is extracted from a region of approximately 10Hz to 20Hz among the wheel speed frequency components. The envelope waveform forming unit 342 scales the extracted unsprung resonance components and forms an envelope waveform using an envelope filter (EnvelopeFilter). The gain multiplier 343 multiplies the gain by the scaled unsprung resonance component to calculate an unsprung vibration damping force control amount and outputs the unsprung vibration damping force control amount to the damping force control unit 35.

(construction of damping force control section)

Next, the configuration of the damping force control unit 35 will be described. Fig. 18 is a control block diagram showing a control structure of the damping force control unit of embodiment 1. The equivalent viscous damping coefficient conversion unit 35a receives the driver input damping force control amount output from the driver input control unit 31, the S/a attitude control amount output from the skyhook control unit 33a, the frequency-sensitive damping force control amount output from the frequency-sensitive control unit 33b, the unsprung damping force control amount output from the unsprung damping force control unit 34, and the stroke speed calculated by the traveling state estimation unit 32, and converts these values into an equivalent viscous damping coefficient.

The damping coefficient arbitration unit 35b arbitrates which damping coefficient among the damping coefficients (hereinafter, each damping coefficient is described as a driver input damping coefficient k1, an S/a attitude damping coefficient k2, a frequency-dependent damping coefficient k3, and an unsprung vibration damping coefficient k4) converted by the equivalent viscous damping coefficient conversion unit 35a is controlled, and outputs the final damping coefficient. The control signal conversion unit 35c converts the damping coefficient and the stroke speed arbitrated by the damping coefficient arbitration unit 35b into a control signal (command current value) for the S/A3, and outputs the control signal to the S/A3.

[ damping coefficient arbitration section ]

Next, the arbitration contents of the damping coefficient arbitration section 35b will be described. The control device for a vehicle of embodiment 1 has four control modes. The first is a standard mode in which a state where a suitable turning state can be obtained on the assumption of traveling in a general urban area or the like, the second is a sport mode in which a state where a stable turning state can be obtained on the assumption of actively traveling in a continuous curve or the like, the third is a comfort mode in which a state where a vehicle is traveling with priority in terms of ride quality is assumed such as at the time of starting at a low vehicle speed, and the fourth is a high-speed mode in which a state where a vehicle is traveling on a highway or the like with a large number of straight lines at a high vehicle speed is assumed.

In the standard mode, the skyhook control by the skyhook control unit 33a is performed, and the unsprung vibration damping control by the unsprung vibration damping control unit 34 is prioritized.

In the sport mode, the skyhook control by the skyhook control unit 33a and the unsprung vibration damping control by the unsprung vibration damping control unit 34 are performed while giving priority to the driver input control by the driver input control unit 31.

In the comfort mode, the frequency-sensing control of the frequency-sensing control unit 33b is performed, and the unsprung vibration damping control of the unsprung vibration damping control unit 34 is prioritized.

In the high-speed mode, the driver input control by the driver input control unit 31 is prioritized, and control is performed in which the control amount of the unsprung vibration damping control by the unsprung vibration damping control unit 34 is added to the skyhook control by the skyhook control unit 33 a.

Next, arbitration of the damping coefficient in each of these modes will be described.

(arbitration in Standard mode)

In step S1, it is determined whether or not the S/a attitude damping coefficient k2 is greater than the unsprung vibration damping coefficient k4, and if it is greater than the unsprung vibration damping coefficient k4, the routine proceeds to step S4, where k2 is set as the damping coefficient.

In step S2, the scalar ratio of the jitter region is calculated from the flight region, the jitter region, and the scalar quantities of the jitter region described in the frequency sensing control unit 33 b.

In step S3, it is determined whether or not the ratio of the jitter region is equal to or greater than a predetermined value, and if the ratio is equal to or greater than the predetermined value, there is a concern that the ride quality will be deteriorated due to the high-frequency vibration, and therefore the process proceeds to step S4, where k2, which is a low value, is set as the damping coefficient. On the other hand, when the ratio of the jitter region is smaller than the predetermined value, there is little concern that the ride quality will be deteriorated due to the high-frequency vibration even if the damping coefficient is set high, and therefore the process proceeds to step S5, where k4 is set as the damping coefficient.

As described above, in the standard mode, the unsprung vibration damping control that suppresses unsprung resonance is prioritized in principle. However, when the damping force required for the skyhook control is lower than the damping force required for the unsprung vibration damping control and the ratio of the shake region is large, the damping force for the skyhook control is set to avoid deterioration of the high-frequency vibration characteristics associated with satisfying the unsprung vibration damping control. This makes it possible to obtain an optimum damping characteristic according to the running state, and to achieve a smooth feeling of the vehicle body while avoiding deterioration of the ride quality due to high-frequency vibrations.

(arbitration in sports mode)

In step S11, the four-wheel damping force distribution ratio is calculated from the driver input damping coefficient k1 for the four wheels set by the driver input control. The calculation is performed by the following equation, where the driver input damping coefficient of the right front wheel is k1fr, the driver input damping coefficient of the left front wheel is k1fl, the driver input damping coefficient of the right rear wheel is k1rr, the driver input damping coefficient of the left rear wheel is k1rl, and the damping force distribution ratio of each wheel is xfr, xfl, xrr, xrl.

xfr＝k1fr/(k1fr+k1fl+k1rr+k1rl)

xfl＝k1fl/(k1fr+k1fl+k1rr+k1rl)

xrr＝k1rr/(k1fr+k1fl+k1rr+k1rl)

xrl＝k1rl/(k1fr+k1fl+k1rr+k1rl)

In step S12, it is determined whether or not the damping force distribution ratio x is within a predetermined range (larger than α, smaller than β), and if it is within the predetermined range, it is determined that the distribution to each wheel is substantially uniform, and the process proceeds to step S13, and if it is outside the predetermined range, the process proceeds to step S16.

In step S13, it is determined whether or not the unsprung vibration damping coefficient k4 is larger than the driver input damping coefficient k1, and if it is determined to be large, the routine proceeds to step S15, where k4 is set as the first damping coefficient k. On the other hand, if it is determined that the unsprung vibration damping coefficient k4 is equal to or less than the driver input damping coefficient k1, the routine proceeds to step S14, where k1 is set as the first damping coefficient k.

In step S16, it is determined whether or not the unsprung vibration damping coefficient k4 is the maximum value max that can be set in S/A3, and if it is determined that the unsprung vibration damping coefficient is the maximum value max, the routine proceeds to step S17, and otherwise, the routine proceeds to step S18.

In step S17, the maximum value of the driver input damping coefficients k1 for the four wheels is calculated as the unsprung vibration damping coefficient k4 and the damping coefficient that satisfies the damping force distribution ratio is calculated as the first damping coefficient k. In other words, the value satisfying the damping force distribution ratio and having the highest damping coefficient is calculated.

In step S18, a damping coefficient that satisfies the damping force distribution ratio in a range where the driver input damping coefficients k1 of the four wheels are all k4 or more is calculated as the first damping coefficient k. In other words, a value is calculated that satisfies the damping force distribution ratio set by the driver input control and also satisfies the request on the unsprung vibration damping control side.

In step S19, it is determined whether or not the first damping coefficient k set in the above steps is smaller than the S/a attitude damping coefficient k2 set in the skyhook control, and if it is determined to be small, the damping coefficient required on the skyhook control side is larger, and therefore the process proceeds to step S20 and is set to k 2. On the other hand, if it is determined that k is equal to or greater than k2, the process proceeds to step S21, where k is set.

As described above, in the sport mode, the unsprung vibration damping control that suppresses unsprung resonance is prioritized in principle. However, the damping force distribution ratio requested from the driver input control side is closely related to the vehicle body posture, and particularly, is deeply related to the change in the driver's sight line due to the roll mode, so that the most priority is to secure the damping force distribution ratio, not the damping coefficient itself requested from the driver input control side. Further, the stable vehicle body posture can be maintained by selecting the skyhook control with a high selection (select high) with respect to the motion that changes the vehicle body posture while maintaining the damping force distribution ratio.

(arbitration in comfort mode)

In step S30, it is determined whether or not the frequency-dependent damping coefficient k3 is larger than the unsprung vibration damping coefficient k4, and if it is determined to be large, the routine proceeds to step S32, where the frequency-dependent damping coefficient k3 is set. On the other hand, if it is determined that the frequency-dependent damping coefficient k3 is equal to or less than the unsprung vibration damping coefficient k4, the routine proceeds to step S32, where the unsprung vibration damping coefficient k4 is set.

As described above, in the comfort mode, the unsprung resonance control that suppresses the unsprung resonance is basically prioritized. Since the frequency-sensitive control is originally performed as the sprung vibration damping control, and the optimum damping coefficient is set in accordance with the road surface condition, it is possible to achieve control that ensures riding comfort and avoid a lack of contact feeling due to unsprung mass vibration damping control. In the comfort mode, the damping coefficient may be switched according to the jitter ratio of the frequency scalar in the same manner as in the standard mode. Thereby, the riding comfort can be further ensured as the super comfort mode.

(arbitration in high speed mode)

Fig. 22 is a flowchart showing the damping coefficient arbitration process in the high-speed mode of embodiment 1. Further, since steps S11 to S18 are the same as the arbitration process in the sport mode, the explanation is omitted.

In step S40, the first damping coefficient k arbitrated up to step S18 is added to the S/a attitude damping coefficient k2 under skyhook control and output.

As described above, in the high-speed mode, the damping coefficient is arbitrated using a value obtained by adding the arbitrated first damping coefficient k to the S/a attitude damping coefficient k 2. Here, the operation will be described with reference to the drawings. Fig. 23 is a time chart showing changes in damping coefficient when the vehicle travels on a rough road surface or a rough road surface. For example, when it is desired to suppress a motion such that a vehicle body is gently shaken due to the influence of a slight undulation or the like of a road surface during running at a high vehicle speed, if it is desired to achieve this only by the skyhook control, it is necessary to detect a slight variation in the wheel speed, and therefore it is necessary to set the skyhook control gain to be high. In this case, a motion such as a light shake can be suppressed, but when a road surface irregularity or the like occurs, the control gain may become excessively large, and an excessive damping force control may be performed. This may deteriorate ride quality and vehicle body posture.

On the other hand, since the first damping coefficient k is always set as in the high-speed mode, a certain degree of damping force is always ensured, and even if the damping coefficient under the skyhook control is small, the movement of the vehicle body such as a light sway can be suppressed. Further, since it is not necessary to increase the skyhook control gain, it is possible to appropriately cope with the road surface irregularities by a normal control gain. In addition, since the skyhook control is performed in a state where the first damping coefficient k is set, the damping coefficient reduction step can be performed in the semi-active control region, unlike the damping coefficient limitation, and a stable vehicle posture can be ensured during high-speed traveling.

(mode selection processing)

Next, a mode selection process for selecting the travel modes will be described. Fig. 24 is a flowchart showing a mode selection process based on the running state in the damping coefficient arbitration unit in embodiment 1.

In step S50, it is determined whether or not the vehicle is in the straight travel state based on the value of the rotation angle sensor 7, and the routine proceeds to step S51 when the vehicle is determined to be in the straight travel state, and proceeds to step S54 when the vehicle is determined to be in the turning state.

In step S51, it is determined whether or not the vehicle speed sensor 8 is equal to or greater than a predetermined vehicle speed VSP1 indicating a high vehicle speed state, and if it is determined that the vehicle speed is equal to or greater than VSP1, the routine proceeds to step S52, where a standard mode is selected. On the other hand, if it is determined to be smaller than the VSP1, the process proceeds to step S53, and the comfort mode is selected.

In step S54, it is determined whether or not the vehicle speed sensor 8 is equal to or greater than a predetermined vehicle speed VSP1 indicating a high vehicle speed state, and if it is determined that the vehicle speed is equal to or greater than VSP1, the routine proceeds to step S55 to select the high speed mode. On the other hand, if it is determined to be smaller than the VSP1, the process proceeds to step S56, and the sport mode is selected.

That is, in the straight traveling state, by selecting the standard mode in the case of traveling at a high vehicle speed, the vehicle body posture under the skyhook control can be stabilized, and by suppressing high-frequency vibrations such as bouncing and chattering, the riding comfort can be ensured, and the unsprung resonance can be further suppressed. Further, by selecting the comfort mode in the case of traveling at a low vehicle speed, unsprung resonance can be suppressed while vibration such as bouncing and shaking is suppressed as much as possible from being transmitted to the passenger.

On the other hand, in the cornering situation, the high-speed mode is selected to perform the control based on the value obtained by adding the damping coefficient when running at a high vehicle speed, and therefore, basically, a high damping force can be obtained. Thus, even at high vehicle speeds, the vehicle body posture during cornering can be actively secured by the driver input control, and unsprung resonance can be suppressed. Further, by selecting the sport mode in the case of low-vehicle-speed running, it is possible to suppress unsprung resonance while actively securing the vehicle body posture at the time of turning and appropriately performing skyhook control by the driver input control, and it is possible to run in a stable vehicle posture.

In addition, although the mode selection processing is described as an example of control for detecting the running state and automatically switching the running state in embodiment 1, for example, a switch or the like that can be operated by the driver may be provided, and the running mode may be selected by control using the switch or the like. This makes it possible to obtain riding comfort and cornering performance according to the driving intention of the driver.

As described above, example 1 exhibits the following effects.

(1) The disclosed device is provided with: an S/a3 (damping force variable shock absorber) provided in the front and rear wheels and capable of changing a damping force; front wheel speed sensors 5FL and 5FR attached to an axle of the front wheel and detecting a wheel speed of the front wheel; wheel speed sensors 5RL, 5RR that detect the wheel speed of the rear wheels from the number of revolutions of the rear drive shaft output from the differential gear of the rear wheels; a sprung rear wheel speed estimating unit 305a and an unsprung rear wheel speed estimating unit 305b (rear wheel speed estimating means) that estimate the rear wheel speed by delaying the front wheel speed detected by the front wheel speed sensors 5FL and 5 FR; damping force control amount calculation means for calculating a damping force control amount of S/a3 from a frequency scalar quantity, when the magnitude of the amplitude of the frequency of the front wheel speed detected by the front wheel speed sensors 5FL and 5FR and the rear wheel speed estimated by the sprung rear wheel speed estimation unit 305a is defined as the frequency scalar quantity; and a damping force control unit 35 (damping force control means) for controlling the damping force of the S/a3 based on the damping force control amount calculated by the damping force control amount calculation means.

Since the change in the wheel speed sensor value is small with respect to the inclination of the axle caused by the stroke of the suspension, and the inclination of the axle is hard to be reflected in the change in the wheel speed sensor value, when the wheel speed of the rear wheel detected by the rear wheel speed sensors 5RL and 5RR is used, the accuracy of estimation of the stroke speed is lowered, and the vibration damping performance may be deteriorated. On the other hand, since the wheel speed sensors 5FL and 5FR attached to the front wheels of the axle have a large change in the value of the wheel speed sensor with respect to the inclination of the axle caused by the stroke, the stroke speed can be estimated with high accuracy. Therefore, by delaying the wheel speed sensor value of the front wheel and estimating the wheel speed of the rear wheel, the accuracy of estimating the stroke speed can be improved and deterioration of the vibration damping performance can be suppressed.

Further, since the damping force control amount of S/a3 is calculated from the frequency scalar quantity, even if a phase shift occurs between the estimated wheel speed of the rear wheel and the actual wheel speed of the rear wheel, the vibration damping performance is not deteriorated, and the vibration damping performance can be improved from the stroke speed estimated with high accuracy.

(2) The frequency-sensitive control unit 33b (damping force control amount calculation means) calculates the frequency-sensitive damping force control amount of S/a3 from the ratio of the shake area in the predetermined frequency area of the wheel speed sensor value.

In vector control in which the relationship of the sign (phase, etc.) of the stroke velocity and the sprung mass velocity is important, such as skyhook control, there is a case where appropriate control is difficult because the phase is slightly shifted, and when the wheel velocity sensor value of the front wheel is delayed to estimate the wheel velocity of the rear wheel, the sign relationship between the stroke velocity and the sprung mass velocity cannot be secured, and therefore there is a possibility that the vibration damping performance is deteriorated. On the other hand, since the frequency-sensitive control, which is sprung vibration damping control corresponding to the scalar quantity of the vibration characteristic, determines the control amount without depending on the sign relationship between the stroke speed and the sprung speed, that is, regardless of the sign, it is possible to improve the vibration damping performance using the wheel speed of the rear wheel estimated by delaying the wheel speed sensor value of the front wheel.

(3) The unsprung vibration damping control unit 34 (damping force control amount calculation means) calculates an unsprung vibration damping force control amount from the amplitude of the unsprung resonance frequency.

The unsprung vibration damping force control amount is calculated by extracting an unsprung resonance component from the wheel speed variation and multiplying the value obtained by scaling the extracted unsprung resonance component by a gain. That is, the control amount is determined regardless of the sign of the stroke speed and the sprung mass speed, regardless of the sign, and therefore, the vibration damping performance can be improved using the wheel speed of the rear wheel estimated by delaying the wheel speed sensor value of the front wheel.

(4) The damping force control amount calculation means generates an envelope amplitude of the frequency, and calculates a frequency scalar from the envelope amplitude.

Specifically, in the frequency-sensitive control, the hilbert transform processing unit 352 performs hilbert transform on each frequency band divided into the empty region, the jitter region, and converts the frequency band into a scalar quantity of amplitude based on the frequency. On the other hand, in the unsprung vibration damping control unit 34, the envelope waveform shaping unit 342 scales the unsprung resonance component extracted by the unsprung resonance component extraction unit 341 and shapes the envelope waveform using an envelope filter.

Therefore, the frequency scalar can be calculated by a simple method.

(5) The rear wheel speed estimating means prohibits the rear wheel speed estimation when the vehicle speed is equal to or higher than a high vehicle speed threshold value V2.

Specifically, when the vehicle speed is equal to or higher than the high vehicle speed threshold value V2, the first wheel speed of the front wheel is not stored in the memory, and the first wheel speed of the rear wheel input from the planar motion component extraction unit 301 is output when the delay time elapses.

(6) The rear wheel speed estimation means prohibits the rear wheel speed estimation when the vehicle speed is less than a low vehicle speed threshold value V1.

Specifically, when the vehicle speed is less than the low vehicle speed threshold value V1, the first wheel speed of the front wheel is not stored in the memory, and the first wheel speed of the rear wheel input from the planar motion component extraction unit 301 is output when the delay time has elapsed.

Claims

1. A control device for a vehicle, comprising:

a damping force variable shock absorber provided to the front and rear wheels, the shock absorber being capable of varying a damping force;

a front wheel speed sensor mounted on an axle of the front wheel for detecting a wheel speed of the front wheel;

a rear wheel speed sensor that detects a wheel speed of the rear wheel based on a number of rotations of a drive shaft output from a differential gear of the rear wheel;

a rear wheel speed estimation unit that estimates a wheel speed of a rear wheel by delaying a wheel speed of a front wheel detected by the front wheel speed sensor;

a damping force control amount calculation means for calculating a damping force control amount of the damping force variable damper based on a frequency scalar quantity, the frequency scalar quantity being a magnitude of an amplitude of a frequency of a front wheel speed detected by the front wheel speed sensor and a rear wheel speed estimated by the rear wheel speed estimation means; and

and a damping force control unit that controls the damping force of the damping force variable absorber based on the damping force control amount calculated by the damping force control amount calculation unit.

2. The control apparatus of a vehicle according to claim 1,

the damping force control amount calculation means calculates the damping force control amount of the damping force variable absorber based on the ratio of the frequency scalar quantity of a predetermined frequency band to the frequency scalar quantities of other frequency bands.

3. The control apparatus of a vehicle according to claim 1 or 2,

the damping force control amount calculation means calculates the damping force control amount of the unsprung vibration damping control from the amplitude of the unsprung resonance frequency.

4. The control device for a vehicle according to any one of claims 1 to 3,

the damping force control amount calculation means generates an envelope amplitude of the frequency, and calculates the frequency scalar quantity from the envelope amplitude.

5. The control device of a vehicle according to any one of claims 1 to 4,

the rear wheel speed estimating means prohibits the estimation when the vehicle speed is equal to or higher than a high vehicle speed threshold.

6. The control device of a vehicle according to any one of claims 1 to 4,

the rear wheel speed estimating means prohibits the estimation when the vehicle speed is less than a low vehicle speed threshold.